Apparatus and methods for performing electrochemical reactions

ABSTRACT

The invention is directed to apparatus and methods for delivering multiple reagents to, and monitoring, a plurality of analytical reactions carried out on a large-scale array of electronic sensors under minimal noise conditions. In one aspect, the invention provides method of improving signal-to-noise ratios of output signals from the electronic sensors sensing analytes or reaction byproducts by subtracting an average of output signals measured from neighboring sensors where analyte or reaction byproducts are absent. In other aspects, the invention provides an array of electronic sensors integrated with a microwell array for confining analytes and/or particles for analytical reactions and a method for identifying microwells containing analytes and/or particles by passing a sensor-active reagent over the array and correlating sensor response times to the presence or absence of analytes or particles. Such detection of analyte- or particle-containing microwells may be used as a step in additional noise reduction methods.

This application is a continuation of U.S. patent application Ser. No. 12/785,716, filed 24 May 2013, which is continuation-in-part of U.S. patent application Ser. Nos. 12/474,897 and 12/475,311, both filed 29 May 2009, and claims priority therefrom and from U.S. provisional patent application Ser. No. 61/306,924 filed 22 Feb. 2010, all of the foregoing being incorporated by reference in their entireties.

BACKGROUND

Electrochemical detection is attractive because it provides high sensitivity, small dimensions, low cost, fast response, and compatibility with microfabrication technologies, e.g. Hughes et al. Science, 254: 74-80 (1991): Mir et al. Electrophoresis, 30: 3386-3397 (2009); Trojanowicz, Anal. Chim. Acta, 653: 36-58 (2009); Xu et al, Talanta, 80: 8-18 (2009); and the like. These characteristics have led to the development of a variety of sensors based on amperometric, potentiometric or impedimetric signals and their assembly into arrays for chemical, biochemical and cellular applications, e.g. Yeow et al, Sensors and Actuators B 44: 434-440 (1997); Martinoia et al, Biosensors & Bioelectronics, 16: 1043-1050 (2001); Hammond et al, IEEE Sensors J., 4: 706-712 (2004); Milgrew et al, Sensors and Actuators B 103: 37-42 (2004); Milgrew et al, Sensors and Actuators B, 111-1 12: 347-353 (2005); Hizawa et al, Sensors and Actuators B, 117: 509-515 (2006); Heer et al. Biosensors and Bioelectronics, 22: 2546-2553 (2007): Barbaro et al, Sensors and Actuators B, 118:41-46 (2006); Anderson et al, Sensors and Actuators B, 129: 79-86 (2008); Rothberg et al, U.S. patent publication 2009/0127589; Rothberg et al, U.K. patent application GB24611127; and the like. In particular, several of these developments involve the use of large-scale arrays of electrochemical sensors for monitoring multiple reaction steps on a large plurality of analytes confined to such an array, e.g. Anderson et al (cited above); Rothberg et al (cited above); and the like. Typically in such systems, analytes are randomly distributed among an array of confinement regions, such as microwells or reaction chambers, and reagents are delivered to such regions by a fluidics system that directs flows of reagents through a flow cell containing the sensor array. Microwells in which reactions take place, as well as empty wells where no reactions take place, may be monitored by one or more electronic sensors associated with each of the microwells.

Such systems are subject to a host of interrelated phenomena that make highly sensitive measurements challenging, particularly under low signal conditions. Such phenomena include unstable reference voltage for the electrical sensors, lack of knowledge as to which confinement regions contain analytes, variability in the amount of reagents delivered by a flow stream to analytes confined to different regions of an array, potential mixing of successively delivered reagents, changes in instrument temperature, fluid leaks that may affect fluid potential, extraneous electrical interference, e.g. 60 Hz noise, cell phones, or the like, all of which may affect the quality of signals collected. In addition, for specific applications, there may further challenges related to particular reagents used, the sensitivity of a sensor for the analyte being measure, the presence or absence of interfering compounds, such as other reaction byproducts, and the like.

In view of the above, it would be advantageous to have available a system for carrying out multi-reagent electrochemical reactions in parallel on a large number of analytes which overcame the deficiencies of current approaches.

SUMMARY OF THE INVENTION

The present invention is directed to apparatus and methods for delivering multiple reagents to a plurality of reactions carried out on, and monitored by, a large-scale array of electronic sensors. In one aspect, such invention provides apparatus and methods for reducing noise in output signals generated by such electronic sensors in response to changes in reaction conditions. The present invention is exemplified in a number of implementations and applications, some of which are summarized below and throughout the specification.

In one aspect, the invention includes an apparatus for performing multi-step electrochemical reactions, wherein a stable reference voltage is provided through a reaction flow chamber to electronic sensors monitoring such multi-step electrochemical reactions. In one embodiment, the apparatus comprises (a) one or more reaction vessels each coupled to an electronic sensor for monitoring products in the reaction vessel, the electronic sensor generating an output signal related to a concentration or presence of a product, the output signal depending on a reference voltage; (b) a fluidics system for sequentially delivering a plurality of electrolytes to the reaction vessel one at a time: and (c) a reference electrode in contact with a selected electrolyte of the plurality, the reference electrode being in fluid communication with the reaction chamber and providing the reference voltage to each electronic sensor without the reference electrode contacting any of the non-selected electrolytes. As described more fully below, in one embodiment, the one or more reaction vessels is an array of microwells disposed on an array of chemFET sensors which, in turn, is disposed in a flow cell in fluid communication with the microwells.

In another aspect, the invention includes an apparatus comprising a sensor array comprising floating gate ion-sensitive field-effect transistors, on which a flow path is defined by a flow cell, such that sensors of the array outside of the flow path are inactivated by electrically connecting their floating gates. In one aspect, such apparatus comprises (a) a sensor array comprising a plurality of sensors formed in a circuit-supporting substrate, each sensor of the array comprising a chemically sensitive field-effect transistor (chemFET) having a floating gate. The chemFET being configured to generate at least one electrical signal related to a concentration or presence of one or more reaction products proximate thereto and a microwell array disposed on the circuit-supporting substrate such that each microwell is disposed on at least one sensor, wherein one or more microwells contain analyte; and (b) a fluidics system for delivering reagents to the microwell array, the fluidics system comprising a flow cell having an inlet, an outlet and a flow chamber that defines a flow path of reagents as they pass from the inlet to the outlet, wherein the flow chamber is configured to deliver the reagents transversely over open portions of the microwells in the flow path, and wherein the floating gates of sensors outside of the flow path are electrically connected and held at a common voltage.

In another aspect, the invention include a method for locating analytes distributed among a plurality of microwells comprising the steps of (a) providing a plurality of microwells disposed on an array of sensors, wherein each microwell has an opening in fluid communication with a flow chamber and is capable of retaining at least one analyte, and wherein each microwell is disposed on at least one sensor configured to provide at least one output signal in response to reagents proximate thereto: (b) changing reagents in the flow chamber from a first reagent in response to which sensors generate a first output signal to a second reagent in response to which sensors to generate a second output signal; and (c) correlating a time delay of a second output signal from a sensor in response to said changing with the presence of an analyte in its corresponding microwell.

In a related aspect, the invention further includes an article of manufacture comprising a sensor array comprising a plurality of sensors formed in a circuit-supporting substrate, each sensor of the array being configured to generate at least one electrical signal related to a concentration or presence of one or more predetermined species proximate thereto and a microwell array disposed on the circuit-supporting substrate such that each microwell thereof has an opening on a surface of the microwell array and is disposed on at least one sensor; and a plurality of analytes randomly distributed in the microwells at locations determinable by an output signal generated by its corresponding sensor. In one embodiment, such analytes each comprise a particle having attached thereto a clonal population of a nucleic acid fragment, such as a genomic DNA fragment, cDNA fragment, or the like.

In another aspect, the invention provides a method of reducing noise in output signals from a sensor array related to reactions and/or analytes disposed in a microwell array. Such method comprises the steps of (a) disposing analyte onto the microwell array such that a portion of the microwells contain analyte: (b) obtaining an output signal generated by a microwell containing analyte or reaction byproduct; and (c) subtracting from such output signal an average of output signals from neighboring microwells that do not contain an analyte or a reaction byproduct.

These above characterized aspects, as well as other aspects, of the present invention are exemplified in a number of illustrated implementations and applications, some of which are shown in the figures and characterized in the claims section that follows. However, the above summary is not intended to describe each illustrated embodiment or every implementation of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A illustrates components of one embodiment of the apparatus of the invention.

FIG. 1B is a diagrammatic illustration of a cross-section of a first example of a fluid-fluid reference electrode interface in which the reference electrode is introduced downstream in the reagent path from the flow cell.

FIGS. 1C and 1D are diagrammatic illustrations of two alternative examples of ways to construct apparatus to achieve the fluid-fluid interface of FIG. 1B.

FIG. 1E is a diagrammatic illustration of a cross-section of a second example of a fluid-fluid reference electrode interface in which the reference electrode is introduced upstream in the reagent path from the flow cell.

FIG. 2A illustrates a section of a flow cell with an external reference electrode and enlargement of an exemplary electronic sensor.

FIG. 2B illustrates the movement of two successive reagents over a section of a microwell array with an ideally uniform flow front between the different reagents.

FIG. 2C illustrates how a particle retards the progress of a sensor-active reagent, thereby creating an output signal time delay that may be used to determine the presence of the particle in the microwell.

FIG. 2D compares output signal data from a microwell with a particle and a microwell without a particle.

FIG. 3A is a diagram illustrating flow paths through a flow chamber having diagonally opposed inlet and outlet.

FIG. 3B is a top view of a mask used for fabricating a sensor array of floating gate chemFETs, where floating gates of chemFETs outside of a diagonal flow region are electrically connected in the manufacturing process, in order to eliminate or minimize noise contributions from unused sensors outside of the diagonal flow region.

FIG. 3C is a display showing the density of analyte deposition in a large-scale microwell array as determined by sensor output signal changes in response to exposure to a step function pH change.

FIG. 4A-4D show different views of flow cell components and their integration with a microwell-sensor array chip.

FIG. 4E shows a flow cell with two flow chambers integrated with a microwell-sensor chip.

FIG. 5A illustrates analytes randomly disposed in microwells of a microwell array.

FIGS. 5B and 5C illustrate different ways of identifying empty microwells in the vicinity of a selected microwell.

FIGS. 6A-6F illustrate the use of signals from local microwells to reduce noise in an output signal of a sensor of a selected microwell.

FIGS. 7A-7C are diagrammatic illustrations of components of an apparatus of the invention adapted for pH-based DNA sequencing.

FIGS. 8A-8C diagrammatically illustrate a fluid circuit for delivering successively different reagents to a flow cell for DNA sequencing, where a reference electrode is in continuous fluid contact with solely a wash solution.

DETAILED DESCRIPTION

While the invention is amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not to limit the invention to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. For example, the microelectronics portion of the apparatus and array is implemented in CMOS technology for purposes of illustration. It should be appreciated, however, that the disclosure is not intended to be limiting in this respect, as other semiconductor-based technologies may be utilized to implement various aspects of the microelectronics portion of the systems discussed herein. Guidance for making arrays of the invention is found in many available references and treatises on integrated circuit design and manufacturing and micromachining, including, but not limited to, Allen et al, CMOS Analog Circuit Design (Oxford University Press, 2nd Edition, 2002); Levinson, Principles of Lithography, Second Edition (SPIE Press, 2005); Doering and Nishi, Editors, Handbook of Semiconductor Manufacturing Technology, Second Edition (CRC Press. 2007); Baker, CMOS Circuit Design, Layout, and Simulation (IEEE Press. Wiley-Interscience, 2008); Veendrick, Deep-Submicron CMOS ICs (Kluwer-Deventer, 1998); Cao. Nanostructures & Nanomaterials (Imperial College Press, 2004); and the like, which relevant parts are hereby incorporated by reference. Likewise, guidance for carrying out electrochemical measurements of the invention is found in many available references and treatises on the subject, including, but not limited to, Sawyer et al, Electrochemistry for Chemists, 2nd edition (Wiley Interscience, 1995); Bard and Faulkner, Electrochemical Methods: Fundamentals and Applications, 2nd edition (Wiley, 2000); and the like, which relevant parts are hereby incorporated by reference.

In one aspect the invention is directed to apparatus and methods for carrying out and monitoring a plurality of multi-step reactions with electronic sensors. The multi-step reactions may be cyclic, such as in DNA sequencing reactions, DNA synthesis reactions, or the like, where repeated cycles of one or more steps are carried out, or they may be non-cyclic, such as in multicomponent labeling reactions, as for example, in a sandwich assay using enzymatic labels. Multi-step reactions may also result from the presence of a biological material, such as living cells or tissue sample, where responses, e.g. the presence or absence of metabolites, are detected in response to a series of reagent exposures, which may be drug candidate molecules, or the like. Preferably, electronic sensors of the invention are integrated into a sensor array suitable for sensing individual reactions taking place on or adjacent to a surface of the array. In one embodiment, an array of reaction confinement regions is integral with such a sensor array. An array of reaction confinement regions may take the form of a microwell array or a reaction chamber array made by conventional micro- or nanofabrication techniques, for example, as described in Rothberg et al, U.S. patent publication US2009/0127589 and Rothberg et al, U.K. patent application GB24611127. In one embodiment, each microwell or reaction chamber in such an array has at least one sensor that is in a sensing relationship so that one or more characteristics of a reaction in the microwell or reaction chamber can be detected or measured. Typically electronic sensors of the invention measure directly or indirectly (for example, by the use of a binding compound or label) reaction byproducts including, but not limited to, chemical species resulting from a reaction or physical changes caused by a reaction, such as increases or decreases in temperature, e.g. as disclosed in Rothberg et at (U.S. and U.K. patent publications cited above). Preferably, electronic sensors of the invention convert changes in the presence, concentration or amounts of reaction byproducts into an output signal, which may be a change in a voltage level or a current level which, in turn, may be processed to extract information about a reaction. Electronic sensors of the array, or a subset of such sensors, may also be used to monitor the presence or concentration of reactants, indicator molecules, or other reagents, such as reagents for identifying microwells containing analytes (described more fully below). The structure and/or design of sensors for use with the invention may vary widely, as exemplified by the following references, which are incorporated by reference: Rothberg et al. U.S. patent publication US2009/0 127589; Rothberg et al, U.K. patent application GB24611127; Barbaro et al, U.S. Pat. No. 7,535,232; Sawada et al, U.S. Pat. No. 7,049,645: Kamahori et al, U.S. patent publication 2007/0059741; Miyahara et al, U.S. patent publications 2008/0286767 and 2008/0286762; O'uchi, U.S. patent publication 2006/0147983; Osaka et al, U.S. patent publication 2007/0207471; Esfandyarpour et al, U.S. patent publication 2008/0166727; and the like. In a preferred embodiment, sensors of the array comprise at least one chemically sensitive field effect transistor that is configured to generate at least one output signal related to a property of a chemical reaction in proximity thereof. Such properties may include a concentration (or a change in concentration) of a reactant or product, or a value of physical property (or a change in such value), such as temperature. Desirable configurations and physical characteristic of electronic sensor arrays and microwell arrays are described more fully below. In one embodiment of such sensor arrays, the chemFETs of the sensors include a floating gate. In another embodiment of the invention, electronic sensors of the array each generate an. output signal that depends in part on the value of the voltage of a reference electrode that is in fluid contact with microwell array. In particular embodiments, a single reference electrode is provided so that each sensor generates output signals with the same reference voltage.

Components of one embodiment of the invention are illustrated diagrammatically in FIG. 1A. Flow cell and sensor array (100) comprise an array of reaction confinement regions (which may comprise a microwell array) that is operationally associated with a sensor array, so that, for example, each microwell has a sensor suitable for detecting an analyte or reaction property of interest. Preferably, a microwell array is integrated with the sensor array as a single chip, as explained more fully below. A flow cell can have a variety of designs for controlling the path and flow rate of reagents over the microwell array. In some embodiments, a flow cell is a microfluidics device. That is, it may be fabricated with micromachining techniques or precision molding to include additional fluidic passages, chambers, and so on. In one aspect, a flow cell comprises an inlet (102), an outlet (103), and a now chamber (105) for defining the flow path of reagents over the microwell array (107). Embodiments of the flow cell are described more fully below. Reagents are discarded into a waste container (106) after exiting flow cell and sensor array (100). In accordance with the invention. a function of the apparatus is to deliver different reagents to flow cell and sensor array (100) in a predetermined sequence, for predetermined durations, at predetermined flow rates, and to measure physical and/or chemical parameters in the microwells that provide information about the status of a reaction taking place therein, or in the case of empty wells, information about the physical and/or chemical environment in the flow cell. To this end, fluidics controller (118) controls by lines (120 and 122) the driving forces for a plurality of reagents (114) and the operation of valves (for example, 112 and 116) by conventional instrument control software, e.g. Lab View (National Instruments, Austin, Tex.). The reagents may be driven through the fluid pathways, valves and flow cell by pumps, by gas pressure, or other conventional methods. In embodiments where a single reference electrode (108) is positioned upstream of flow cell and sensor array (100), preferably a single fluid or reagent is in contact with reference electrode (108) throughout an entire multi-step reaction. This is achieved with the configuration illustrated in FIG. 1A where reagents I through K (114) are directed through passage (109) to flow cell (105). When those reagents are flowing, valve (112) is shut, thereby preventing any wash solution from flowing into passage (109). Although the flow of wash solution is stopped, there is still uninterrupted fluid and electrical communication between reference electrode, passage (109), and sensor array (107). At most reagents I through K when flowing through passage (109) diffuse into passage (111), but the distance between reference electrode (108) and the junction between passages (109) and (111) is selected so that little or no amount of the reagents flowing in common passage (109) reach reference electrode (108). Although FIG. 1A and other figures illustrate an electrode (for example, reference electrode, 108) as a cylinder concentric with a fluid passage (for example. 111), reference electrodes, such as (108), may have a variety of different shapes. For example, it could be a wire inserted into the lumen of (111). In one aspect, reference electrode (108) constitutes a section of passage (112) that is made of a conductive material, such as stainless steel, gold, or the like. Preferably the material is inert with respect to reagents in contact with it. Reference electrode (108) in one embodiment is a tube made of a conductive material which forms part of passage (112). Generally in the figures, whenever electrodes are represented as a cylinder concentric with a flow path, such figure element is intended to comprise electrodes having a variety of configurations, as noted, but with a preferred configuration as a tube of conductive material enclosing part of a flow path.

The value of the reference voltage depends on the interface between the electrode and the solution in which the electrode is in contact. It has been observed and appreciated that (for example) solutions of different nucleoside triphosphates cause the reference voltage to change, thereby causing undesirable changes in the output signals of the sensors. For multi-step reactions using frequent wash steps, wash solution (110) may be selected as the reagent in continuous contact with reference electrode (108) as illustrated in FIG. 1A. (That is, the wash solution would be the “selected electrolyte” or “selected reagent” and the dNTP reagents would be the “non-selected electrolytes” or “non-selected reagents” as the terms are used elsewhere herein). As further described below, in certain DNA sequencing methods washes are implemented after each introduction of nucleoside triphosphates; thus, in such methods a wash solution is preferably in continuous contact with reference electrode. Such contact may be obtained by including a reservoir for holding the selected electrolyte, such as the wash solution, which is connected by a branch passage (e.g. 111) to a common passage (e.g. 109) for delivering electrolytes to a reaction vessel. In one aspect, the branch passage has a valve disposed between the reservoir (e.g., 110) and a junction with the common passage, wherein the reference electrode is disposed in the branch passage between the valve and the junction such that the reference electrode is in fluid communication with the reaction vessel and such that whenever the valve (e.g. 112) is shut and fluid within the branch passage is stationary, substantially no non-selected electrolyte contacts the reference electrode. The only transfer of non-selected electrolyte into the branch passage is by diffusion; thus, the reference electrode may be place sufficiently far away from the junction so that minimal or no non-selected electrolyte reaches it during the time the selected electrolyte is stationary.

Further components of this embodiment include array controller (124) for providing bias voltages and timing and control signals to the sensor array (if such components are not integrated into the sensor array), and for collecting and/or processing output signals. Information from flow cell and sensor array (100), as well as instrument settings and controls may be displayed and entered through user interface (128). For some embodiments, for example, nucleic acid sequencing, the temperature of flow cell and sensor array (100) is controlled so that reactions take place and measurements are made at a known, and preferably, a predetermined temperature. Such temperature may be controlled by conventional temperature control devices, such as, a Peltier device, or the like. In one aspect, temperature is conveniently controlled by controlling the temperatures of the reagents flowing through the flow cell. Noise in output signals due to temperature differences within an array or due to temperature fluctuations may be recorded by temperature reference sensors within the array, as described in Rothberg et al (published patent application cited above). Such noise may then be subtracted from the output signal in conventional signal processing techniques.

FIG. 2A is an expanded and cross-sectional view of flow cell (200) showing a portion (206) of a flow chamber with reagent flow (208) moving across the surface of microwell array (202) over the open ends of the microwells. Preferably, microwell array (202) and sensor array (205) together form an integrated unit forming a bottom wall or floor of flow cell (200). In one embodiment, reference electrode (204) is fluidly connected to flow chamber (206). A microwell (201) and sensor (214) are shown in an expanded view. Microwell (201) may be formed by conventional microfabrication technique, as described briefly below. Microwell volume, shape, aspect ratio (such as, base width-to-well depth ratio), and the like, are design choices that depend on a particular application, including the nature of the reaction taking place, as well as the reagents, byproducts, and labeling techniques (if any) that are employed. Sensor (214) is a chemFET with floating gate (218) having sensor plate (220) separated from the microwell interior by passivation layer (216). Sensor (214) is predominantly responsive to (and generates an output signal related to) the amount of charge (224) present on the passivation layer (216) opposite of sensor plate (220). Changes in charge (224) cause changes in the current between source (221) and drain (222) of the FET, which may be used directly to provide a current-based output signal or indirectly with additional circuitry to provide a voltage output signal. Reactants, wash solutions, and other reagents move into microwells from flow chamber (206) primarily by diffusion (240).

Typically reactions carried out in microwells (202) are analytical reactions to identify or determine characteristics or properties of an analyte of interest. Such reactions generate directly or indirectly byproducts that affect the amount of charge adjacent to sensor plate (220). (Indirect detection may occur, for example, if byproduct chelators or other binding compounds are used that affect the sensor after binding an analyte of interest, or if labeling moieties are employed, such as enzymes that may generate a secondary byproduct as the result of a binding event, or the like) If such byproducts are produced in small amounts or rapidly decay or react with other constituents, then multiple copies of the same analyte may be analyzed in microwell (201) at the same time in order in increase the output signal ultimately generated. In one embodiment, multiple copies of an analyte may be attached to solid phase support (212), either before or after deposition into a microwell. Solid phase supports (212) may include microparticles, nanoparticles, beads, solid and porous, comprising gels, and the like. For nucleic acid analytes, multiple, connected copies may be made by rolling circle amplification (RCA), exponential RCA, and like techniques, to produce an amplicon without the need of a solid support.

As mentioned above, in one aspect, flow cells of the invention constrain reagents to move transversely in a laminar flow over a microwell array. The rate of flow is a design choice depending on the nature of the reactions carried out, the geometry and size of the flow chamber and microwell array, and the like. Generally, however, when different reagents are successively delivered to the microwells, a flow cell delivers each new reagent flow with a uniform flow front as it transits the flow chamber during the switch from one reagent to another. That is, flow cell design and reagent flow rate are selected so that as one reagent follows another with little or no mixing occurring at the boundary between the successive fluids. FIG. 2B illustrates a uniform flow front between two reagents moving across section (234) of a microwell array. A “uniform flow front” means that successive reagents, e.g. reagent 1 (232) and reagent 2 (230), undergo little or no mixing as the reagents move across the microarray, thereby keeping boundary (236) between reagent 1 (232) and reagent 2 (230) narrow as it moves across a microarray. Such boundaries may be linear for flow cells having inlets and outlets at opposite ends of their flow chambers, or such boundaries may be curvilinear for flow cells having central inlets (or outlets) and peripheral outlets (or inlets).

Reference Electrodes for Electronic Sensor Arrays

The fluid-electrode interface influences the way the reference potential is transmitted into the fluid. That is, the interface potential between the fluid and the electrode fluctuates with the composition of the fluid (which may be somewhat turbulent and inhomogeneous), introducing a voltage offset to the potential of the bulk fluid which varies with time and possibly location, as well. Considerably greater reference potential stability may be achieved by moving the location of the reference electrode so that it is substantially isolated from changes in fluid composition. This may be accomplished by introducing a conductive solution of a consistent composition over at least part of the surface of the electrode (hereafter the “electrode solution” or “selected electrolyte”), arranging the electrode to avoid it coming into direct contact with the changing fluids in the flow cell and instead, arranging the electrode solution (not the electrode) to come into electrical contact with the fluid in the flow cell. The result is a transfer of the reference potential to the flow cell solution (be it a reagent or wash or other solution) that is considerably more stable than is obtained by direct insertion of an electrode into the flow cell solution. We refer to this arrangement as a liquid-liquid or fluid-fluid reference electrode interface. The fluid-fluid interface may be created downstream from the flow cell, upstream from the flow cell (as exemplified in FIG. 1A), or in the flow cell. Examples of such alternative embodiments are shown in Figs. FIGS. 1B-1E.

Turning first to FIG. 1B, there is shown a diagrammatic illustration of an embodiment in which the fluid-fluid interface is created downstream from the flow cell. In this example, the flow cell apparatus 131 is, as above, mounted on a chip 132 which contains the sensor array (not shown). The flow cell apparatus includes an inlet port 133 and an outlet port 134. That is, the reagent fluids are introduced into port 133 via conduit 134 and they exit via port 134. A first port 136 of a fluid “Tee” connector 137 is coupled onto flow cell outlet port 134 via conventional couplings to receive the fluid exiting from the flow cell. A reference electrode such as a hollow electrically conductive tube 138 is fed into another port of the Tee connector via a fluid-tight coupling 139. The reference electrode is connected to a reference potential source 140 and a suitable electrode solution 141 is flowed into the center bore of the electrode tube.

Two modes of operation are possible. According to a first mode, the electrode solution may be flowed at a rate that is high enough to avoid backflow or diffusion from the fluid flowing out of the flow cell. According to a second mode, once the electrode solution has filled the electrode and come into contact with the outlet flow from the flow cell, a valve (not shown) may be closed to block further flow of the electrode solution into the electrode and, as the electrode solution is an incompressible liquid, there will be substantially no flow into or out of the electrode, yet the fluid-fluid interface will remain intact. This presumes, of course an absence of bubbles and other compressible components. For a fluid-fluid interface to take the place of a metal-fluid interface, the tip 142 of the electrode 138 is positioned to stop within the Tee connector short of the fluid flow out of the flow cell, so that it is the “electrode solution,” not the electrode itself, that meets the outlet flow from the flow cell, indicated at 143, and carries the reference potential from the electrode to the reagent solution exiting the flow cell. The two fluid streams interact in the Tee connector at 143 and if the electrode solution is flowing, it flows out the third port 144 of the Tee connector with the reagent flow, as a waste fluid flow, for disposal. This approach eliminates interfacial potential changes at the electrode surface. Using a fluid-fluid interface to convey a stable reference potential from a reference electrode to a flow cell, various alternative embodiments are possible.

In one alternative, illustrated in FIG. 1C, the referencing junction (i.e., the fluid-fluid interface) can be moved into the structure of the members forming the flow cell or even into the sensor chip itself, but with the electrode solution never entering the flow cell. For example, a manifold 151 may be formed in the flow cell assembly outside the flow chamber itself, having an inlet 152 for receiving electrode solution and an outlet 153 in fluid communication with the flow cell's outlet conduit 134. The electrode may be a separate element disposed in the manifold or it may be a metallization applied to an interior surface of the manifold.

Alternatively, the manifold can be formed in the substrate of the chip itself by fabricating in the substrate a hollow region which can serve as a conduit allowing fluid passage from an inlet end to an outlet end. An electrode may be inserted therein via a separate inlet port 152 or part of the (interior or exterior, as appropriate) surface of the conduit may be metalized during fabrication, to serve as the electrode. The flow path for reagent fluid to exit the flow chamber may include a conduit portion and the electrode conduit manifold may deliver electrode solution to the reagent fluid outlet conduit, wherein the two fluids come into contact to provide the fluid-fluid interface that applies the reference electrode voltage to the flow cell.

In each instance, the electrode may be hollow and have the electrode solution delivered through its interior, or the electrode solution may be delivered over the exterior of the electrode. For example, as shown in FIG. 1C, the electrode may be hollow, such as being the interior surface of the manifold 151, and it may have an exterior that is insulated from the flow cell using any suitable structure and material (not shown, to avoid obfuscation of the basic idea).

The electrode assembly thus may be built into the sensor chip itself or into the flow cell or its housing, coupled with a fluid inlet through which electrode solution may be introduced. The flow path for reagent fluid to exit the flow chamber may include a conduit portion 134 into which the electrode solution is presented, and wherein the two fluid flows come into contact to provide the fluid-fluid interface. The electrode solution may flow or be static.

As a further alternative embodiment, depicted in FIG. 1D, the electrode structure may be integrated into or disposed within the flow cell itself. This may be done in two distinctly different ways. First, the electrode solution may be introduced into the flow chamber and flowed from an inlet 154 into the flow cell (provided for that purpose) to an outlet port 134 through which both the electrode solution and the reagent flow exit the flow chamber. If both fluids are arranged to move through the chamber in a laminar flow, they will not intermix (or there will be little mixing and interaction) until they reach the outlet. So there need not be a barrier between the two fluids. Their entire region of contact will be the locus of fluid-fluid interfacing, which may provide considerably more surface for that interface than the other illustrated alternatives. Second, a fluid conduit may be provided adjacent to the flow chamber or even fully or partly within the flow chamber, with a non-conductive exterior. The electrode may extend along the interior of the conduit, between an electrode fluid inlet and a fluid outlet that permits the electrode solution to interface with the reagent flow, such as in a common outlet conduit 134.

In the foregoing examples, the reference potential is introduced either in or downstream of the flow cell. However, the same approach is possible with the electrode provided upstream of the flow cell, as shown diagrammatically in FIG. 1E. There, 133 is the inlet port to the flow cell and 134 is the outlet port, as in FIG. 1B. A cross-connector 171 having four ports has a first port 172 coupled onto the inlet port. A second port, 173, receives the solution to be reacted or measured (e.g., a reagent) via inlet conduit 135. A third port, 174, is used as a waste outlet port. The fourth port, 175, receives the electrode in the same manner as previously shown in FIG. 1B. Within the cross-connector, the electrode solution and the solution to be reacted/measured interact to transmit the reference potential into the flow cell. In contrast with some of the other alternative embodiments, however, at least some implementations of this embodiment may require that the solution to be measured/reacted must have a sufficiently high flow rate as to prevent flow of the electrode solution into the flow chamber. However, with judicious configuring of the cross-connector, it may still be possible to avoid the need to flow electrode solution continuously.

Use of Electronic Sensors to Locate Analytes in Microwells

In one aspect of the invention, electronic sensors are used to locate microwells that contain analyte and/or particles and microwells that are empty. Such a process is useful because output signals from empty wells allows the estimation of common noise components that may be subtracted from output signals measured from analyte-containing microwells, thereby improving signal-to-noise ratios. Moreover, in many embodiments analytes and/or particles are randomly disposed in microwells by placing them in solution and flowing them into the flow chamber where they settle randomly into microwells, as illustrated in FIG. 3A, and further exemplified in Rothberg et al (U.S. patent publication cited above); thus, a method of electronically identifying which microwells contain analyte and which are empty is needed.

Usually, only a single analyte is disposed in a single microwell. In one aspect, multiple copies of the same analyte are attached to solid support, such as a bead or particle, which, in turn, is selected to match a microwell in size and shape so that only a single solid support fits into a single microwell, thereby ensuring only one kind of analyte is in a single microwell. As mentioned above, for some types of analytes, such as nucleic acids, methods are available, such as rolling circle amplification (RCA), or the like, to construct connected amplicons that form a single body that may exclusively occupy a microwell, e.g. as disclosed in Drmanac et al, U.S. patent publication 2009/0137404. After the random distribution of analytes into microwells, electronic sensors responsive to changes in surface charge may be used to identify microwells containing analyte. Thus, in one aspect, a method of the invention includes introducing a sensor-active reagent, which may be the same or different as a reagent used in an analytical process of interest, which is capable of altering the charge adjacent to a sensor as a function of its concentration.

In one embodiment, this aspect of the invention may comprise the following steps: (a) changing reagents in a flow chamber from a first reagent that sensors generate in response thereto a first output signal to a second reagent that sensors to generate in response thereto a second output signal; and (b) correlating a time delay in the generation of a second output signal by a sensor in response to said changing with the presence of an analyte in its corresponding microwell. Any type of electrochemical sensor may be used in this aspect of the invention, including a potentiometric sensor, an impedimetric sensor, or an amperometric sensor, so long as the output signal depends on the interaction of an electrode or other analyte-sensitive surface and the sensor-active reagent whose arrival is delayed by physical or chemical obstructions in a microwell. In one embodiment, the sensor-active reagent is a wash solution at a different pH than the reagent it replaces, which may also be the wash solution. The step of changing reagents includes recording the output signals of the sensors in the array so that a continuous time record of signal values (or a digital representation thereof) is obtained which can be analyzed to determine the timing of changes in output signals that correspond to the times at which the sensor-active reagent reach the respective sensors. Such data recording and analysis may be carried out by conventional data acquisition and analysis components.

As illustrated in FIG. 2C, when sensor-active reagent flows into the flow chamber, it diffuses from flow chamber (206) through microwell (201) that contains particle (212) as well as through microwell (250) and to the region of passivation layer (216) opposite of sensor plate (220). Whenever microwell (201) contains analyte or particle (212) diffusion front (252) of the charging reagent is retarded relative to front (254) in empty well (250) either by the physically obstruction in the diffusion pathway by the analyte/particle or by chemical interactions with the analyte/particle or its associated solid support, if present. Thus, microwells containing analyte may be determined by correlating a time delay (256) in the change of output signal of the sensor with the presence of analyte/particle. In one embodiment, where the sensors are configured to measure pH, the charging reagent is a solution having a predetermined pH, which is used to replace a first reagent at a different predetermined pH. In embodiments for nucleic acid sequencing, the retardation of hydrogen ion diffusion is affected both by the physical obstruction and buffering capacity of the analyte and/or particle. Preferably, the first reagent pH is known and the change of reagents effectively exposes sensors of the microwells to a step-function change in pH, which will produce a rapid change in charge on their respective sensor plates. In one embodiment, a pH change between the first reagent and the charging reagent (or sometimes referred to herein as the “second reagent” or the “sensor-active” reagent) is 2.0 pH units or less; in another embodiment, such change is 1.0 pH unit or less; in another embodiment, such change is 0.5 pH unit or less; in another embodiment, such change is 0.1 pH unit or less. The changes in pH may be made using conventional reagents, e.g. HCl, NaOH, or the like. Exemplary concentrations of such reagents for DNA pH-based sequencing reactions are in the range of from 5 to 200 μM, or from 10 to 100 μM. The variation in charge at a microwell surface opposite a sensor plate indicative of the presence or absence of analyte (or a byproduct from a reaction on an analyte) is measured and registered as a related variation in the output signal of the sensor, e.g. a change in voltage level with time. FIG. 2D shows data from sensors on an array manufactured in accordance with Rothberg et al, U.S. patent publication 2009/0127589, with sensor layout, pitch (9 μm), and floor plan as described in FIGS. 10, 11A, and 19. A microwell corresponding to a first sensor is loaded with a 5.9 μm diameter bead with template, primer and polymerase attached and a microwell corresponding to a second sensor is empty. The output signals from each sensor are recorded while the reagent in a flow cell is changed from pH 7.2 to pH 8.0 and maintained at the pH 8.0 value for 5.4 sec. Curve (270) shows the values of the output signal from the first sensor (whose microwell contains a bead) and curve (272) shows values of the output signal from the second sensor (whose microwell is empty). Both curves show a change from a high value corresponding to pH 7.2 to a low value corresponding to pH 8.0. However, the signal corresponding to the empty well reaches the low value noticeably faster than the signal corresponding to the bead-bearing microwell. The difference in time, Δt (274), at which the respective output signals reach the lower value, or a comparable measure, is readily determined with conventional data analysis techniques. Locations and densities of particle-containing microwells within an array may be displayed graphically in a number of ways, including as a contour map or “heat” map, as illustrated in FIG. 3C.

In one aspect of the invention, microwell arrays may be provided with locations of randomly distributed analytes determined. Such a product, or article of manufacture, comprises (i) a sensor array comprising a plurality of sensors formed in a circuit-supporting substrate, each sensor of the array being configured to generate at least one electrical signal related to a concentration or presence of one or more predetermined species proximate thereto and a microwell array disposed on the circuit-supporting substrate such that each microwell thereof has an opening on a surface of the microwell array and is disposed on at least one sensor; and (ii) a plurality of analytes randomly distributed in the microwells at locations determinable by an output signal generated by its corresponding sensor. In one embodiment, the analytes comprise particles having attached thereto clonal populations of DNA fragments, e.g. genomic DNA fragments, cDNA fragments, or the like.

Flow Cells and Output Signal Collection

Flow cell designs of many configurations are possible; thus the system and methods presented herein are not dependent on use of a specific flow cell configuration. Design and performance specifications of a flow cell of the invention include, but are not limited to the following: (i) minimization of the time required to change reagents that analytes are exposed to, (ii) minimization of mixing of successive reagents, that is, providing a uniform flow front between successive reagents, (iii) provide a laminar flow and uniform transit times of fluids across an array (including minimization or elimination of any regions (such as dead volumes) where fluids become trapped so that mixing between successive flows can occur), (iv) provide sufficient volume of flow over microwells (for example, by providing a flow chamber of sufficient volume above the microwell array) so that efficient exchange of material by diffusion occurs between the microwell volumes and the flow), (v) minimization of bubble formation (including reducing sharp corners or edges that promote bubble formation, controlling dissolved gas in the reagents, and providing surfaces that are readily wetted by aqueous reagents), (vi) facilitation of the placement of a reference electrode, (vii) facilitation of loading analytes into microwells or reaction chambers in an array, and the like.

In one aspect, a flow cell of the invention directs reagent flows to a microwells array such that each microwell is exposed to substantially the same flow conditions, including flow rate, concentration, and the like, at substantially the same time throughout the microwell array, as reagents are delivered to the array. By “substantially the same time” in reference to such exposure it is meant that the transit time through the flow chamber of a boundary between two successive reagents is small in comparison to the length of time a microwell is exposed to any one reagent. For some flow cell configurations identical flow rates at each microwell are not possible, such as with flow cells having inlets and outlets located diagonally in a flow chamber constrained to a rectilinear space. Nonetheless, a preferred design feature is that differences in flow conditions, such as flow rate, experienced by different microwells are minimized by a flow chamber and the flow path it defines. As mentioned above, a flow cell can have a variety of designs for achieving the above performance and manufacturing criteria, such as disclosed in Rothberg et al, U.S. patent publication 2009/0127589; Rothberg et al, U.K. patent application GB24611127. A flow cell of the invention that meets such design and performance criteria is illustrated in FIGS. 4A to 4E. The illustrated designs provide for simple manufacture where a flow cell is formed by attaching a component with inlet and outlet to a chip or encapsulated microwell array-sensor array unit. In this embodiment, a flow chamber is the interior space formed when such pieces are combined, or attached to one another. In the design, an inlet is positioned at a corner of the flow chamber and an outlet at the diagonally opposed corner. This design is simple in that it requires only two manufactured pieces and the diagonal positioning of the inlet and outlet minimizes regions (e.g. (301) in FIG. 3A) of the flow chamber where reagent may be trapped or their transit times retarded. FIG. 3A illustrates flow paths (300) of a reagent as it transits a flow chamber along its diagonal axis from inlet (302) to outlet (304). In one embodiment, a flow chamber is defined by reference to such flow paths, as shown in FIG. 3B. That is, in the example of FIG. 4A, walls (410) and the boundary (307) (defining “pinned” sensors, described more fully below) are shaped to substantially follow the flow paths that reagents would follow through a square or rectangular flow chamber with diagonally opposed inlet and outlet. The result is that reagent flows are confined to central region (308) and corner regions (306), where reagents could mix or form eddies, are rendered inaccessible. The curvature of boundary (307) may be estimated (for example using a section of a quadratic or like standard curve) or it may be computed using commercially available fluid dynamics software, e.g., SolidWorks from Dassault Systems (Concord, Mass.); Flowmaster from FlowMaster USA, Inc. (Glenview, Ill.); and OpenFOAM (open source code for computational fluid dynamics available on the world wide web, www.openefd.co.uk). In embodiments employing floating gate chemFETs as sensors, preferably, sensors in the reagent-inaccessible regions (306) are electrically connected so as not to introduce spurious voltage levels into output signals generated in those sections of the sensor array. That is, in such embodiments, readout circuitry of the sensor array continues to readout all columns and all rows, so that specialized circuits or programming is not required to avoid the sensors in the inaccessible regions. Instead, constant predetermined output signals are registered from sensors in such regions.

In one aspect of the invention described above, reaction chambers or microwells containing analytes are identified by introducing successive reagents (referred to herein as a first reagent and a predetermined reagent) into the flow cell that change the charge sensed by the sensors of the array in a predetermined manner. As shown in FIG. 3C, results of such identification may be displayed as a density map of the microwell array (310) in the flow chamber, where the distribution of analytes within microwells of the array are indicated by color scale (312). In this embodiment, colors of scale (312) indicate a local percentage of microwells (e.g. percentage of each non-overlapping regions of 100 microwells) containing analytes throughout the array, except for unused regions (306).

Flow cells may be assembled with a microwell array and sensor array in a variety of ways, such as disclosed in Rothberg et al, U.S. patent publication 2009/0127589 and Rothberg et al, U.K. patent application GB24611127, which are incorporated by reference. In one embodiment, illustrated in FIGS. 4A-4D, a flow cell is made by attaching a fluidic interface member to a housing containing a sensor chip. Typically, an integrated microwell-sensor array (i.e., a sensor chip) is mounted in a housing or package that protects the chip and provides electrical contacts for communicating with other devices. A fluidics interface member is designed to provide a cavity or flow chamber for reagents to pass through when it is sealingly attached to such packaging. In one aspect, such attachment is accomplished by gluing the pieces together. FIG. 4A shows a bottom view (or face) of component (400) (referred to below as a “rectilinear body”) of a flow cell of the invention. In the illustrated embodiment, a complete flow cell is formed by attaching component (400) to a package containing a sensor array (as shown in FIGS. 4C and 4D). Ridge (401) is elevated from surface (413) and forms walls (410) of ellipsoidal flow chamber (408) when mated with chip (430) shown in FIG. 4C. Component (400) may be glued to chip housing (430) (referred to below generically as “rectilinear interface package”) to form a fluid-tight seal. FIG. 4B shows a top view (or face) (416) of component or member (400) showing inlet and outlet collars (418) and (420) that permit the flow cell to be sealingly connected to a fluidic system. Inlet and outlet tubes connected to elastomeric annular members that are inserted into collars (418) and (420) so that the elastomeric material forms a seal along the floor and walls of collars (418) and (420). Other means of connecting a flow cell to a fluidics system may be used, including other types of pressure fittings, clamp-based fittings, screw-on fittings, or the like, which are design choices for one of ordinary skill Component (400) may be adapted to accommodate different sized chips with a simple design change, as illustrated by passages (422) and (424). Namely, for a small array (434) shown in FIG. 4C, a passage having an opening at the center of inlet collar (418) and of outlet collar (420) may be directed by such passage towards the center of component or member (400) to an inlet port and outlet port over array (430). Likewise, for a large array (436), shown in FIG. 4D, similar passages (442 and 444) may be directed away from the center of component (400) and to the inlet and outlet of array (436). This has the advantage of providing a single basic flow cell design that can be used with multiple sensor array sizes. Protruding tab (412) and bevel (414) are employed to ensure correctly oriented placement of a chip into a complementary socket or appliance for making fluidic and electrical connections to the rest of the apparatus.

In one aspect, the invention includes a flow cell member (exemplified in FIGS. 4A and 4B) for forming a fluidics interface with sensor arrays of different rectilinear sizes disposed in a rectilinear interface package. Such a member comprises the following elements: (a) a rectilinear body having an upper face and a lower face and a shape matched with that of the rectilinear interface package so that the lower face of the rectilinear body may be bonded to the rectilinear interface package to form a fluid-tight enclosure for a sensor array, wherein an inlet is disposed at one end of the upper face, and an outlet is disposed at an opposite end of the upper face; (b) an inlet passage interior to the rectilinear body providing a fluid passage from the inlet to the fluid-tight enclosure forming an inlet port in the lower face of the rectilinear body positioned above and at one end of the sensor array; and (c) an outlet passage interior to the rectilinear body providing a fluid passage from the outlet to the fluid-tight enclosure forming an outlet port in the lower face of the rectilinear body positioned above and at an end of the sensor array opposite of that of the inlet port. In one embodiment, the inlet is concentrically disposed with an inlet collar in a corner of said upper face and said outlet is concentrically disposed with an outlet collar in a diagonally opposite corner of said upper face as said inlet and inlet collar. In another embodiment, the inlet and outlet collars each have a radius and wherein said inlet port and said outlet port are each positioned within perpendicular projections of the radii of said inlet and outlet collars, respectively, onto said lower face of said rectilinear body. In another embodiment, a plurality of fluid-tight enclosures are formed when a rectilinear body is bonded to a rectilinear interface package, as exemplified in FIG. 4E.

FIG. 4E illustrates how the above design concepts may be used to make a plurality of separate flow cells using a single large sensor array. Fluidics interface member (462) mounts on and is sealingly attached to a housing (not shown) that holds sensor array (450) and defines two flow chambers (451) and (453), each having separate inlets (454 and 456, respectively) and separate diagonally opposed outlets (458 and 460, respectively) that are connected to a common source of reagents and to a common waste line, respectively. Interior walls (480, 482, 484 and 486) formed by attachment of fluidics interface member (452) to the chip housing defines the flow paths through flow chambers (451) and (453) and exclude opposing corner regions (470, 474, 476, and 478) from having contact with reagents passing through the flow chambers. Preferably, in embodiments employing floating gate FETs, sensors in corner regions (470, 474, 476, and 478) are pinned as described above. Likewise. sensors in the region defined by, or under, central partition (462) are also pinned so that they do not contribute to output signal noise of active sensors.

Flow cells and fluidic circuits of the invention (described below) may be fabricated by a variety of methods and materials. Factors to be considered in selecting materials include degree of chemical inertness required, operating conditions, e.g. temperature, and the like, volume of reagents to be delivered, whether or not a reference voltage is required, manufacturability, and the like. For small scale fluid deliveries, microfluidic fabrication techniques are well-suited for making fluidics circuits of the invention, and guidance for such techniques is readily available to one of ordinary skill in the art, e.g. Malloy, Plastic Part Design for Injection Molding: An Introduction (Hanser Gardner Publications, 1994); Herold et al. Editors, Lab-on-a-Chip Technology (Vol. I): Fabrication and Microfluidics (Caister Academic Press. 2009); and the like. For meso-scale and larger scale fluid deliveries, conventional machining techniques may be used to fabricate parts that may be assembled into flow cells or fluidic circuits of the invention. In one aspect, plastics such as polycarbonate, polymethyl methacrylate, and the like, may be used to fabricate flow cells and fluidics circuits of the invention.

As mentioned above, analytes are randomly distributed in microwells of an array, as illustrated for array section (500) in FIG. 5A, where microwells either are empty (501) or contain analyte (502), such as a bead. Output signals collected from empty wells may be used to reduce or subtract noise in output signals collected from sensors of microwells containing analyte. Empty well output signals contain signal noise components common to all microwells within a local region of the array, so that such common noise components may be obtained from the empty well output signals and subtracted from the output signal of microwells with analyte using conventional signal processing techniques. In other words, output signals from wells containing analyte are improved by subtracting a component of noise determined from output signals of neighboring empty wells. In one aspect, a measure of such common noise is based on an average of output signals from multiple neighboring empty wells. As described more fully below in the case of DNA sequencing, the type of information used from neighboring microwells and how it is used may vary with nature of assays being carried out and measured. As used herein, the term “average” includes weighted averages, and functions of averages, for example, based on models of physical and chemical processes taking place in the microwells. Types of microwells used in the averages may be generalized in particular applications where, for example, further sets of microwells may be analyzed for further information on common noise, such as, in addition to empty wells, wells containing particles without analyte may be included, and so on. In one embodiment, time domain functions of average empty well noise may be converted to frequency domain representations and Fourier analysis, e.g. using fast Fourier transforms, may be used to remove common noise components from output signals from non-empty well. As mentioned above, the empty well signal subtracted in this manner may be an average of empty well signals of empty wells in the vicinity of a microwell of interest. The number and location of local empty wells for such computation may be selected and carried out in a variety of ways. Exemplary approaches for making such selections are illustrated in FIGS. 5B and 5C. In FIG. 5B, for each microwell containing analyte (504), a fixed region (506) may be defined by a 7×7 Square, (505) of microwells. In other embodiments, such a fixed region may vary in the range from 3×3 to 101×101, or in the range from 3×3 to 25×25. Selection of the size of such regions depends on several factors, including the degree of loading of analytes in microwells, the amount of time available for computing during a step, and the like. Returning to FIG. 5B, output signals from empty wells in region (506) are used in the above subtraction computation. Alternatively, a region of empty wells may be determined by distance from the microwell of interest, as illustrated in FIG. 5C. There fixed circular region (512) is defined by a distance (510) from the microwell of interest (504) and empty well signals from empty wells falling entirely within region (512), that is, in region (508), are used in the above subtraction computation. Not all of the empty well signals in a given region need be used. For example, when a microwell array is sparsely loaded with analytes or particles, e.g. less than 25 percent microwells being loaded, a portion of the empty wells in a defined region (e.g. 512) may be used for background subtraction. In one aspect, such portion or subset may be a randomly selected subset of available empty wells. In some circumstances it may be advantageous to use the least number of empty well output signals as possible in order to minimize computation time for determining output signals from non-empty wells. The area and/or number of wells selected for determining an average empty well signal may change according to the density of analytes in microwells. For example, the size of a local region may be selected depending on the availability of empty wells. If a minimum of N empty well output signals, e.g. 10, 20, or 30, must be measured to ensure a reliable representation of local noise, then a local region, e.g. (512), may be increased until such number is present. In one aspect, local noise subtraction using a fixed area is used whenever ninety-five percent or less of the microwells in an array contain analyte. In some embodiments, in addition to, or in lieu of empty wells, particles carrying analyte may be spiked with particles not carrying analyte and the background noise subtraction may be with respect to an average signal recorded for microwells containing analyte-free particles.

System for Nucleic Acid Sequencing

In one aspect, the invention provides methods and apparatus for carrying out label-free DNA sequencing, and in particular, pH-based DNA sequencing. The concept of label-free DNA sequencing, including pH-based DNA sequencing, has been described in the literature, including the following references that are incorporated by reference: Rothberg et al, U.S. patent publication 2009/0026082; Anderson et al. Sensors and Actuators B Chem., 129: 79-86 (2008); Pourmand et al, Proc. Natl. Acad. Sci., 103: 6466-6470 (2006); and the like. Briefly, in pH-based DNA sequencing, base incorporations are determined by measuring hydrogen ions that are generated as natural byproducts of polymerase-catalyzed extension reactions. In one embodiment, templates each having a primer and polymerase operably bound are loaded into reaction chambers (such as the microwells disclosed in Rothberg et al, cited above), after which repeated cycles of deoxynucleoside triphosphate (dNTP) addition and washing are carried out. In some embodiments, such templates may be attached as clonal populations to a solid support, such as a microparticle, bead, or the like, and such clonal populations are loaded into reaction chambers. For example, templates may be prepared as disclosed in U.S. Pat. No. 7,323,305, which is incorporated by reference. As used herein, “operably bound” means that a primer is annealed to a template so that the primer's 3′ end may be extended by a polymerase and that a polymerase is bound to such primer-template duplex, or in close proximity thereof so that binding and/or extension takes place whenever dNTPs are added. In each addition step of the cycle, the polymerase extends the primer by incorporating added dNTP only if the next base in the template is the complement of the added dNTP. If there is one complementary base, there is one incorporation, if two, there are two incorporations, if three, there are three incorporations, and so on. With each such incorporation there is a hydrogen ion released, and collectively a population of templates releasing hydrogen ions changes the local pH of the reaction chamber. The production of hydrogen ions is monotonically related to the number of contiguous complementary bases in the template (as well as the total number of template molecules with primer and polymerase that participate in an extension reaction). Thus, when there is a number of contiguous identical complementary bases in the template (i.e. a homopolymer region), the number of hydrogen ions generated, and therefore the magnitude of the local pH change, is proportional to the number of contiguous identical complementary bases. (The corresponding output signals are sometimes referred to as “1-mer”, “2-mer”, “3-mer” output signals, and so on). If the next base in the template is not complementary to the added dNTP, then no incorporation occurs and no hydrogen ion is released (in which case, the output signal is sometimes referred to as a “O-mer” output signal.) In each wash step of the cycle, an unbuffered wash solution at a predetermined pH is used to remove the dNTP of the previous step in order to prevent misincorporations in later cycles. Usually, the four different kinds of dNTP are added sequentially to the reaction chambers, so that each reaction is exposed to the four different dNTPs one at a time, such as in the following sequence: dATP, dCTP, dGTP, dTTP, dATP, dCTP, dGTP, dTTP, and so on, with each exposure followed by a wash step. The process is illustrated in FIG. 6D for template (682) with primer binding site (681) attached to solid phase support (680). Primer (684) and DNA polymerase (686) operably bound to template (682). Upon the addition (688) of dNTP (shown as dATP), polymerase (686) incorporates a nucleotide since “T” is the next nucleotide in template (682). Wash step (690) follows, after which the next dNTP (dCTP) is added (692). Optionally, after each step of adding a dNTP, an additional step may be performed wherein the reaction chambers are treated with a dNTP-destroying agent, such as apyrase, to eliminate any residual dNTPs remaining in the chamber, which may result in spurious extensions in subsequent cycles.

In one embodiment, a sequencing method exemplified in FIG. 6D may be carry out using the apparatus of the invention in the following steps: (a) disposing a plurality of template nucleic acids into a plurality of reaction chambers disposed on a sensor array, the sensor array comprising a plurality of sensors and each reaction chamber being disposed on and in a sensing relationship with at least one sensor configured to provide at least one output signal representing a sequencing reaction byproduct proximate thereto, and wherein each of the template nucleic acids is hybridized to a sequencing primer and is bound to a polymerase: (b) introducing a known nucleotide triphosphate into the reaction chambers; (c) detecting incorporation at a 3′ end of the sequencing primer of one or more nucleotide triphosphates by a sequencing reaction byproduct if such one or more nucleotide triphosphates are complementary to corresponding nucleotides in the template nucleic acid: (d) washing unincorporated nucleotide triphosphates from the reaction chambers: and (c) repeating steps (b) through (d) until the plurality of template nucleic acids are sequenced. For embodiments where hydrogen ion is measured as a reaction byproduct, the reactions further should be conducted under weak buffer conditions, so that the maximum number of hydrogen ions reacts with a sensor and not extraneous components (e.g. microwell or solid supports that may have surface buffering capacity) or chemical constituents (in particular pH buffering compounds). In one embodiment, a weak buffer allows detection of a pH change of at least ±0.1 in said reaction chamber, or at least ±0.01 in said reaction chambers.

Several potential sources of noise may affect output signals from sensors when a large number of electrochemical reactions are carried out in a microwell array integrated with a sensor array, such as described by Rothberg et al (cited above). Such sources of noise include thermal sensitivity of the sensors, electrical potential disturbances in the fluid (such as resistive or thermal noise in the fluids, reference voltage changes due to different fluids contacting the reference electrode, and the like) and pH changes due to bulk changes in fluids that are passed over the sensor array (referred to herein as “reagent change noise”). Additional sources of noise may also arise in DNA sequencing applications from the nature of a particular DNA sequencing chemistry employed. For example, noise may arise due to the stochastic behavior of polymerase function (incomplete extensions) or failure to completely wash away all dNTPs, in a given step (inappropriate incorporation), e.g. Chen et al. International patent publication W0/2007/098049.

Thermal sensitivity of a sensor array is addressed by maintaining the sensor array at a predetermined temperature that is suitable for extension reactions and that permits measurement of hydrogen ion concentrations and/or changes in the pH. In one aspect, such temperature is within the range of from 25° C. to 75° C. Preferably the predetermined temperature is constant throughout the entire multistep reaction. Such temperature may be regulated by conventional techniques, e.g. Peltier device, or the like. In one embodiment, temperature is maintained by controlling the temperature of the reagents that flow through the flow cell, such that the rate of flow and heat capacity of the fluid is sufficient to remove excess heat generated by the sensors or analytical reactions.

As mentioned above, disturbances in the reference voltage arise from a variety of sources, including changes in the type of fluid a reference electrode is in contact with, and noise from other components of the fluidics system. For example, other components of the fluidics system may act as antennas for extraneous electrical noise. e.g. 60 Hz noise, noise from power supplies, and the like, which affect the reference voltage. In accordance with the invention, a reference electrode is provided that contacts only one kind of reagent throughout a sequencing operation, thereby eliminating a component of reference voltage variability. In another aspect, low frequency noise introduced into the fluidics system may be reduced or eliminated by capacitively coupling the reference electrodes to other components of the fluidics system, such sections of reagent passages in the fluidic systems, as illustrated in FIGS. 7B and 7C.

Another source of noise may arise when successive reagent flows pass over a sensor array (i.e., reagent change noise). The magnitude of such noise depends on several factors including the nature of the measurement being made (e.g. pH, inorganic pyrophosphate (PPi), other ions, or the like) whether a leading or trailing reagent in a reagent change has a property or constituent, e.g. pH, which affects sensor performance and the magnitude of the influence, the relative magnitude of the reagent change effect in comparison with the reaction signal being monitored, and so on. For pH-based DNA sequencing applications (for example), pH-sensitive sensors may generate a signal in response to a reagent change in that is large in comparison to the signal due to hydrogen ion byproduct, as illustrated by the data of FIG. 6A. In such applications, different reagents, such as solutions containing different dNTPs, have slightly different buffering capacities and pKa's, so that at a boundary of different reagent flows, e.g. a wash solution flow followed by a dNTP flow, the sensors register a significant voltage change, as illustrated in FIGS. 2D and 6A. FIG. 6A shows the magnitudes of four output signals from different microwells of a DNA sequencing chip as disclosed is Rothberg et al (cited above), which employs conventional ion-sensitive field-effect transistor (ISFET) sensors. Curves (606) illustrate signals from microwells during a wash step with no changes in reagent. Curve (600) shows an output signal from a microwell containing a particle with template attached where a primer on the template has been extended by one nucleotide. Curve (602) is the output signal from a microwell that contains a particle with a template where there has been no extension. Region (604) is the difference between the two output signals ((602) and (604)) that is due to generation of hydrogen ion in the microwell where extension has taken place. Curve (608) in FIG. 6B, which is the difference between the values of curves (600) and (602), is the part of the raw output signal of curve (600) which is due to hydrogen ion produced in the extension reaction, i.e. the signal of interest. In accordance with the invention, such reagent change noise and other noise components common to local groups of microwells may be subtracted from an output signal of a selected sensor by using information from output signals generated from neighboring microwells. In one embodiment, such neighboring microwell information is obtained from at least one average value of output signals from a plurality of neighboring wells. In another embodiment, neighboring microwell information is obtained from output signals of empty wells. In still another embodiment, neighboring microwell information is obtained from output signals of non-empty microwells where no extension reaction took place. Correction of raw output signals by subtracting reagent change noise may be carried out after each reagent change based on averages computed after each such change, or such corrections may be carried out using averages computed from a previous reagent change, depending on the rate at which averages change during a multi-step or multi-cycle electrochemical process. For example, in a DNA sequencing embodiment, an average may be computed for each different dNTP flow in a cycle (where a succession of the four different dNTPs is introduced into reaction chambers) and used to correct raw output signals for from 1 to 5 cycles of reagent change.

As is noted from FIG. 2D, output signals from neighboring microwells may be systematically altered relative to signals from a microwell of interest depending on the type of neighboring microwells selected for noise subtraction. For example, in FIG. 2D, the same phenomena (e.g., signal delay) that permits the detection of empty wells, may also require that such signals must be transformed to account for such differences if subtraction from the signal of interest is going to make sense. For example, because the presence of a particle in the microwell of interest distorts the signal corresponding to reagent change (delay and flattening due to chemical interaction with the particle), an empty well signal must be modified to remove the changes due to the absence of a particle and chemical interactions, which may readily be done using conventional numerical analysis. If neighboring microwell information is restricted to only 0-mer neighbors, then such transformation is much less, or not necessary, in order to subtract reagent change noise from a signal of interest As mentioned above, “an average” of neighboring microwell output signals may include weighted averages or transforms of the neighboring microwells average output signals to reflect the different physical and chemical conditions of the selected microwell and its neighbors. Steps of an embodiment of such a process are illustrated in FIG. 6C. Raw output signal RS_(i)(j), for times j=1, 2 . . . t. recorded by a sensor of selected microwell, M_(i), is read (660). “Raw output signal” means the recorded values of the output signal prior to data analysis. Neighboring microwells are defined (662) so that raw output signals of neighboring microwells. RN_(k)(j), can also be read (664). Definitions of neighbors may include a local region from where neighbor signals are collected, for example, as described for FIGS. 5A-5C, and such definitions may include the types of neighboring microwells whose output signals are taken, e.g. empty wells, microwells with analyte or particle but no reaction, and the like. In one aspect, neighboring output signals are selected from neighboring microwells that are as physically and chemically similar to the Mi microwell, except for the presence of a signal, e.g. pH level, from the analyte that is to be detected or measured. After raw output signals from neighboring microwells are read, an average, A (j), is computed (666) and subtracted (668) from raw output signal, RSi(j), to give a noise-reduced output signal, Si(j).

FIG. 6E illustrates another embodiment that uses an average neighbor signal to remove noise from a signal of interest (e.g. change in pH due to nucleotide incorporation). The figure shows two neighboring microwells (631) and (641) at four different times: before a next reagent is introduced (t₀), immediately after the next reagent is exposed to the microwells (t), a time during equilibration of the next reagent with the microwell contents (t₂), and after equilibrium has been achieved (t₃). The change in sensor signal due to such a reagent change is described as a two compartment model, where one compartment is the next reagent (e.g. the next flow of dNTPs) in region (638) adjacent to the opening of a microwell and the other compartment is the surface (640) at the bottom of a microwell adjacent to the sensor. Immediately after new reagent (630) enters a flow cell a concentration difference (636) is created between the two compartments, so that a flux of hydrogen ions is established both in microwells with particles φ_(b) (632) and in empty wells φ_(e) (634). For microwells having particles (633) where extension reactions occur, hydrogen ions are also created, which adds to the flux. Eventually equilibrium is reached (642) and the flux of hydrogen ions goes to zero. One of ordinary skill in the art would recognize that a variety of alternative models and models of differing complexity are available for describing the physical and chemical phenomena of the electrochemical reactions taking place in the microwells. Returning to the model of FIG. 6E, the generation of hydrogen ions by extension reactions and the fluxes through microwells with beads and those without may be described by simple reaction-diffusion equations, which give the change in hydrogen ion concentrations at the sensors, as illustrated by the following equations:

$\frac{s_{t} - s_{b}}{\alpha_{b}} = {\varphi_{b} = {\frac{\partial s_{b}}{\partial t}\beta_{b}}}$ $\frac{s_{t} - s_{e}}{\alpha_{e}} = {\varphi_{e} = {\frac{\partial s_{e}}{\partial t}\beta_{e}}}$

where α_(b) and α_(e) are diffusion constants of the hydrogen ions in the solvent, and β_(b) and β_(e) are constants that reflect the interaction (e.g. buffering) of the hydrogen ions with microwell wall and/or particle or analyte in the microwell. Manipulation of these terms and integration of the differentials gives s_(b) as a function of s_(e) and an integral of the differences between s_(b) and s_(e). To this expression is added a source term, I_(ext), for the hydrogen ions generated in an extension reaction.

$s_{b} = {{s_{e}R} + \frac{{\int s_{e}} - s_{b}}{\tau_{b}} + I_{ext}}$

where R=(α_(e)β_(e)/α_(b)β_(b)). Curves for s_(b) are readily generated numerically for fitting data to remove reagent change noise. FIG. 6F illustrates data fit by such a model and use of the model to subtract reagent change noise. Panel (650) shows an output signal (652) (“NN Data”) from a sensor of a microwell in which extension reactions occur when exposed to flows of dATP and dGTP. Curve (654) (“Model Background”) is from the above model of the reagent change noise. Panel (656) shows curve (658) which models both the reagent change noise and the generation of hydrogen ions. Panel (659) shows output signal (657) after the reagent change noise has been subtracted.

In FIG. 6D, each template includes calibration sequence (685) that provides a known signal in response to the introduction of initial dNTPs. Preferably, calibration sequence (685) contains at least one of each kind of nucleotide. In one aspect, calibration sequence (685) is from 4 to 6 nucleotides in length and may contain a homopolymer or may be non-homopolymeric. Calibration sequence information from neighboring microwells may be used to determine which neighboring microwells contain templates capable of being extended which, in turn, allows identification of neighboring microwells that may generate 0-mer signals, 1-mer signals, and so on, in subsequent reaction cycles. Information from such signals from neighboring microwell may be used to subtract undesired noise components from output signals of interest. In other embodiments, an average 0-mer signal may be modeled (referred to herein as a “virtual 0-mer” signal) by taking into account (i) neighboring empty well output signals in a given cycle, and (ii) the effects of the presence of a particle and/or template on the shape of the reagent change noise curve. The latter factor as noted in FIG. 2D is a delay, which is reflected in a flattening and shifting in the positive time direction of an output signal of a particle-containing microwell relative to an output signal of an empty well. As noted, such effects are readily modeled to convert empty well output signals to virtual 0-mer output signals, which may be used to subtract reagent change noise.

FIG. 7A diagrammatically illustrates an apparatus that may be used to carry out pH-based nucleic acid sequencing in accordance with Rothberg et al. U.S. patent publication 2009/0026082. Housing (700) containing fluidics circuit (702, described more fully below) is connected by inlets to reagent reservoirs (704, 706, 708, 710, and 712), to waste reservoir (720), and to flow cell (734) by passage (732) that connects fluidics node (730) to inlet (738) of flow cell (734). Reagents from reservoirs (704, 706, 708, 710, and 712) may be driven to fluidic circuit (702) by a variety of methods including pressure, pumps, such as syringe pumps, gravity feed, and the like, and are selected by control of valves (714). Controller (718) includes controllers for valves (714) that generate signals for opening and closing via electrical connection (716). Controller (718) also includes controllers for other components of the system, such as wash solution valve (724) connected thereto by (722). Array controller (719) includes control and data acquisition functions for flow cell (734) and reference electrode (728). In one mode of operation, fluidic circuit (702) delivers a sequence of selected reagents (1, 2, 3, 4, or 5) to flow cell (734) under programmed control of controller (718), such that in between selected reagent flows fluidics circuit (702) is primed and washed, and flow cell (734) is washed. Fluids entering flow cell (734) exit through outlet (740) and are deposited in waste container (736). Throughout such an operation, the reactions and/or measurements taking place in flow cell (734) are assured a stable reference voltage because fluidics circuit (702) provides reference electrode (728) with a continuous, i.e. uninterrupted, electrolyte pathway with flow cell (734), although it is in physical contact with only the wash solution.

FIGS. 7B and 7C illustrate further measures that may be taken to reduce noise introduced into other parts of fluidics system that may affect the reference voltage. In FIG. 7B, electrode (752) forming part of waste stream (754) is coupled to reference electrode (728) by capacitor (750), which filters low frequency noise introduced through waste stream (754). Likewise, as shown in FIG. 7C, such electrodes (761, 763, 765, 767, and 769) may be fitted on flow paths for process reagents, such as reagents 1 through 5, and coupled to reference electrode (728) through separate capacitors (760, 762, 764, 766, and 768, respectively).

Fluidics Circuits for Sequential Reagent Delivery

As mentioned above, in one embodiment, a reference electrode of the invention is kept in contact with only a single reagent by use of a fluidic circuit, such as (702) in FIG. 7A. FIGS. 8A-8C diagrammatically illustrate an embodiment of a fluidics circuit which provides this contact for the reference electrode and which accommodates five input reagents in a planar circuit structure. FIG. 8A is a top view of a transparent body or housing (800) containing fluidic circuit (802) which may comprise a microfluidics device. Housing (800) may be constructed from a variety of materials, including metals, glass, ceramics, plastics, or the like. Transparent materials include polycarbonate, polymethyl methacryate, and the like. Inlets (or input ports) (804, 806, 808, 810, and 812) are connected by a passage to their respective connector slots (814) located on the bottom side of housing (800) (shown as double circles concentric with the inlets) from which reagents enter fluidic circuit (802). Inlets (804, 806, 808, 810, and 812) are in fluid communication with passages (805, 807, 809, 811, and 813, respectively) which, in turn, are connected to curvilinear passages (824, 826, 828, 830, and 832, respectively). Each curvilinear passage consists of two legs, such as (836) and (838), identified for curvilinear passage (824) at a “T” junction (835), also identified for only curvilinear passage (824). One leg is an inner leg (for example (838)) which connects its respective inlet to node (or multi-use central port) (801) and the other leg is an outer leg (for example (836)) which connects its respective inlet to waste passage (or ring) (840). As mentioned above, the cross-sectional areas and lengths of the inner and outer legs of the curvilinear passages may be selected to achieve the desired balance of flows at the “T” junctions and at node (801). Through passage (844), waste passage (or channel) (840) is in fluid communication with waste port (845) which connects to a waste reservoir (not shown) by connector slot (846) on the bottom side of body (800). Node (801) is in fluid communication with port (860) by passage (861) which in this embodiment is external to body (800) and is illustrated by a dashed line. In other embodiments, passage (861) may be formed in body (800) so that connector slots for node (801) and port (860) are not required. Port (860) is connected by passage (863) to wash solution inlet (862), where a “T” junction is formed, and to connector slot (864) which, in turn, provides a conduit to a flow cell, reaction chamber, or the like. FIGS. 8B and 8C illustrate two of three modes of using the fluidics circuit to distribute fluids to a flow cell. The modes of operation are implemented by valves (850) associated with each of the input reagents and with the wash solution. In a first mode of operation (selected reagent valve open, all other reagent. valves closed, wash solution valve closed) (FIG. 8B), a selected reagent is delivered to a flow cell; in a second mode of operation (selected reagent valve open, all other reagent valves closed, wash solution valve open) (FIG. 8C), the fluidic circuit is primed to deliver a selected reagent; and in a third mode of operation (all reagent valves closed, wash solution valve open) (not shown), all passages in the fluidics circuit are washed. As mentioned above, associated with each inlet is a valve (850) which can be opened to allow fluid to enter fluidic circuit (802) through its respective inlet (as shown for valve (852)), or closed to prevent fluid from entering circuit (802) (as shown with all valves, except for (852)). In each case, when an inlet's valve is open and the others are closed (including the wash solution valve) as shown for inlet (870) in the FIG. 8B, fluid flows through passage (854) to “T” junction (856) where it is split into two flows, one of which is directed to waste passage (840) and then the waste port (845), and another of which is directed to node (801). From node (801) this second flow again splits into multiple flows. one of which exits node (801) through passage (861) and then to passage (863) and to a flow cell, and the other flows to each of the passages connecting node (801) to the other inlets, and then to waste passage (840) and waste port (845). The latter flows pass the other inlets carrying any material diffusing or leaking therefrom and directing it to waste port (845). A sequence of different reagents may be directed to a flow cell by opening the valve of a selected reagent and simultaneously closing the valves of all of the non-selected reagents and the wash solution. In one embodiment, such sequence may be implemented by a sequence of operating modes of the fluidics circuit such as: wash, prime reagent x_(i), deliver reagent x_(i), wash, prime reagent x₂, deliver reagent x₂, wash, and so on. The reagent priming mode of operation is illustrated in FIG. 8C. As in the reagent delivery mode, all reagent inlet valves are closed, except for the valve corresponding to the selected reagent. Unlike the reagent delivery mode, however, the wash solution valve is open and the relative pressure of the selected reagent flow and the wash solution flow is selected so that wash solution flows through passage (861) and into node (801) where it then exits through all the passages leading to waste passage (840), except for the passage leading to the selected reagent inlet.

DEFINITIONS

“Amplicon” means the product of a polynucleotide amplification reaction; that is, a clonal population of polynucleotides, which may be single stranded or double stranded, which are replicated from one or more starting sequences. The one or more starting sequences may be one or more copies of the same sequence, or they may be a mixture of different sequences that contain a common region that is amplified, for example, a specific exon sequence present in a mixture of DNA fragments extracted from a sample. Preferably, amplicons are formed by the amplification of a single starting sequence. Amplicons may be produced by a variety of amplification reactions whose products comprise replicates of the one or more starting, or target, nucleic acids. In one aspect, amplification reactions producing amplicons are “template-driven” in that base pairing of reactants, either nucleotides or oligonucleotides, have complements in a template polynucleotide that are required for the creation of reaction products. In one aspect, template-driven reactions are primer extensions with a nucleic acid polymerase or oligonucleotide ligations with a nucleic acid ligase. Such reactions include, but are not limited to, polymerase chain reactions (PCRs), linear polymerase reactions, nucleic acid sequence-based amplification (NASBAs), rolling circle amplifications, and the like, disclosed in the following references that are incorporated herein by reference: Mullis et al, U.S. Pat. Nos. 4,683,195; 4,965,188; 4,683,202; 4,800,159 (PCR); Gelfand et al. U.S. Pat. No. 5,210,015 (real-time PCR with “taqman” probes); Wittwer et al, U.S. Pat. No. 6,174,670; Kacian et al, U.S. Pat. No. 5,399,491 (“NASBA”): Lizardi, U.S. Pat. No. 5,854,033: Aono et al, Japanese patent publ. JP 4-262799 (rolling circle amplification); and the like. In one aspect, amplicons of the invention are produced by PCRs. As used herein, the term “amplifying” means performing an amplification reaction. A “reaction mixture” means a solution containing all the necessary reactants for performing a reaction, which may include, but not be limited to, buffering agents to maintain pH at a selected level during a reaction, salts, co-factors, scavengers, and the like. A “solid phase amplicon” means a solid phase support, such as a particle or bead, having attached a clonal population of nucleic acid sequences, which may have been produced by a process such as emulsion PCR, or like technique.

“Analyte” means a molecule or biological cell of interest that directly affects an electronic sensor at a sample retaining region, such as a microwell, or that indirectly affects such an electronic sensor by a byproduct from a reaction involving such molecule or biological cell located in such a sample retaining region, or reaction confinement region, such as a microwell. In one aspect, analyte is a nucleic acid template that is subjected to a sequencing reaction which, in turn, generates a reaction byproduct, such as hydrogen ions, that affects an electronic sensor. The term “analyte” also comprehends multiple copies of analytes, such as proteins, peptide, nucleic acids, or the like, attached to solid supports, such as beads or particles. In a one embodiment, the term “analyte” means a nucleic acid amplicon or a solid phase amplicon.

“Microfluidics device” means an integrated system of one or more chambers, ports, and channels that are interconnected and in fluid communication and designed for carrying out an analytical reaction or process, either alone or in cooperation with an appliance or instrument that provides support functions, such as sample introduction, fluid and/or reagent driving means, temperature control, detection systems, data collection and/or integration systems, and the like. Microfluidics devices may further include valves, pumps, and specialized functional coatings on interior walls, e.g. to prevent adsorption of sample components or reactants, facilitate reagent movement by electroosmosis, or the like. Such devices are usually fabricated in or as a solid substrate, which may be glass, plastic, or other solid polymeric materials, and typically have a planar format for case of detecting and monitoring sample and reagent movement, especially via optical or electrochemical methods. Features of a microfluidic device usually have cross-sectional dimensions of less than a few hundred square micrometers and passages typically have capillary dimensions. e.g. having maximal cross-sectional dimensions of from about 500 μm to about 0.1 μm. Microfluidics devices typically have volume capacities in the range of from 1 μL to a few nL, e.g. 10-100 nL. The fabrication and operation of microfluidics devices are well-known in the art as exemplified by the following references that are incorporated by reference: Ramsey, U.S. Pat. Nos. 6,001,229; 5,858,195; 6,010,607; and 6,033,546; Soane et al, U.S. Pat. Nos. 5,126,022 and 6,054,034; Nelson et al, U.S. Pat. No. 6,613,525; Maher et al, U.S. Pat. No. 6,399,952; Ricco et al. International patent publication WO 02/24322; Bjornson et al, International patent publication WO 99/19717; Wilding et al, U.S. Pat. Nos. 5,587,128; 5,498,392; Sia et al, Electrophoresis, 24: 3563-3576 (2003); Unger et al, Science, 288: 113-116 (2000); Enzelberger et al, U.S. Pat. No. 6,960,437.

“Microwell,” which is used interchangeably with “reaction chamber,” means a special case of a “reaction confinement region,” that is, a physical or chemical attribute of a solid substrate that permit the localization of a reaction of interest. Reaction confinement regions may be a discrete region of a surface of a substrate that specifically binds an analyte of, interest, such as a discrete region with oligonucleotides or antibodies covalently linked to such surface. Usually reaction confinement regions are hollows or wells having well-defined shapes and volumes which are manufactured into a substrate. These latter types of reaction confinement regions are referred to herein as microwells or reaction chambers, and may be fabricated using conventional microfabrication techniques, e.g. as disclosed in the following references: Doering and Nishi, Editors, Handbook of Semiconductor Manufacturing Technology, Second Edition (CRC Press, 2007); Saliterman, Fundamentals of BioMEMS and Medical Microdevices (SPIE Publications, 2006); Elwenspoek et al, Silicon Micromachining (Cambridge University Press, 2004); and the like. Preferable configurations (e.g. spacing, shape and volumes) of microwells or reaction chambers are disclosed in Rothberg et al, U.S. patent publication 2009/0127589; Rothberg et al, U.K. patent application GB24611127, which are incorporated by reference. Microwells may have square, rectangular, or octagonal cross sections and be arranged as a rectilinear array on a surface. Microwells may also have hexagonal cross sections and be arranged as a hexagonal array, which permit a higher density of microwells per unit area in comparison to rectilinear arrays. Exemplary “Configurations of microwells are as follows: In some embodiments, the reaction chamber array comprises 10², 10³, 10⁴, 10⁵, 10⁶ or 10⁷ reaction chambers. As used herein, an array is a planar arrangement of elements such as sensors or wells. The array may be one or two dimensional. A one dimensional array is an array having one column (or row) of elements in the first dimension and a plurality of columns (or rows) in the second dimension. The number of columns (or rows) in the first and second dimensions may or may not be the same. Preferably, the array comprises at least 100,000 chambers. Preferably, each reaction chamber has a horizontal width and a vertical depth that has an aspect ratio or about 1:1 or less. Preferably, the pitch between the reaction chambers is no more than about 10 microns. Briefly, in one embodiment microwell arrays may be fabricated as follows: After the semiconductor structures of a sensor array are formed, the microwell structure is applied to such structure on the semiconductor die. That is, the microwell structure can be formed right on the die or it may be formed separately and then mounted onto the die, either approach being acceptable. To form the microwell structure on the die, various processes may be used. For example, the entire die may be spin-coated with, for example, a negative photoresist such as Microchem's SU-8 2015 or a positive resist/polyimide such as HD Microsystems HD8820, to the desired height of the microwells. The desired height of the wells (e.g., about 3-12 μm in the example of one pixel per well, though not so limited as a general matter) in the photoresist layer(s) can be achieved by spinning the appropriate resist at predetermined rates (which can be found by reference to the literature and manufacturer specifications, or empirically), in one or more layers. (Well height typically may be selected in correspondence with the lateral dimension of the sensor pixel, preferably for a nominal 1:1-1.5:1 aspect ratio, height:width or diameter.) Alternatively, multiple layers of different photoresists may be applied or another form of dielectric material may be deposited. Various types of chemical vapor deposition may also be used to build up a layer of materials suitable for microwell formation therein. In one embodiment, microwells are formed in a layer of tetra-methyl-ortho-silicate (TEOS). The invention encompasses an apparatus comprising at least one two-dimensional array of reaction chambers. wherein each reaction chamber is coupled to a chemically-sensitive field effect transistor (“chemFET”) and each reaction chamber is no greater than 10 μm³ (i.e., I pL) in volume. Preferably, each reaction chamber is no greater than 0.34 pL, and more preferably no greater than 0.096 pL or even 0.012 pL in volume. A reaction chamber can optionally be 2², 3², 4², 5², 6², 7², 8², 9², or 10² square microns in cross-sectional area at the top. Preferably, the array has at least 10², 10³, 10⁴, 10⁵, 10⁶, 10⁷, 10⁸, 10⁹, or more reaction chambers. The reaction chambers may be capacitively coupled to the chemFETs, and preferably are capacitively coupled to the chemFETs.

“Primer” means an oligonucleotide, either natural or synthetic that is capable, upon forming a duplex with a polynucleotide template, of acting as a point of initiation of nucleic acid synthesis and being extended from its 3′ end along the template so that an extended duplex is formed. Extension of a primer is usually carried out with a nucleic acid polymerase, such as a DNA or RNA polymerase. The sequence of nucleotides added in the extension process is determined by the sequence of the template polynucleotide. Usually primers are extended by a DNA polymerase. Primers usually have a length in the range of from 14 to 40 nucleotides, or in the range of from 18 to 36 nucleotides. Primers are employed in a variety of nucleic amplification reactions, for example, linear amplification reactions using a single primer, or polymerase chain reactions, employing two or more primers. Guidance for selecting the lengths and sequences of primers for particular applications is well known to those of ordinary skill in the art, as evidenced by the following references that are incorporated by reference: Dieffenbach, editor, PCR Primer: A Laboratory Manual, 2nd Edition (Cold Spring Harbor Press, New York, 2003). 

1.-31. (canceled)
 32. An apparatus comprising: a reaction vessels coupled to an electronic sensor for monitoring a reaction product in the reaction vessel; a fluidics system for sequentially delivering a plurality of reagents to the reaction vessel, the fluidics system including a plurality of reagent reservoirs in fluidic communication via a plurality of flow paths with a fluidics circuit and to a common passage in fluidic communication between the fluidics circuit and the reaction vessel, a solution reservoir in fluidic communication with the common passage via a branch passage connected with the common passage at a junction between the fluidics circuit and the reaction vessel; and a electrode in contact with a solution within the branch passage, the electrode being in electrical communication with the reaction vessel through fluid extending from the branch passage and through the common passage, the electronic sensor generating an output signal depending on a voltage of the electrode.
 33. The apparatus of claim 32Error! Reference source not found, wherein the electrode is in contact with the solution and does not contact any of the plurality of reagents.
 34. The apparatus of claim 32, wherein the electrode provides a reference voltage to the electronic sensor.
 35. The apparatus of claim 32, wherein the reaction vessel includes a well of an array of wells disposed on an array of chemically sensitive field-effect transistor sensors, the electronic sensor comprising a chemically sensitive field-effect transistor sensor of the array of chemically sensitive field-effect transistor sensors.
 36. The apparatus of claim 35, wherein the fluidics system comprises a flow cell in fluid communication with the wells and configured to deliver reagents of the plurality of reagents to each well of the array of wells at substantially the same flow rate.
 37. The apparatus of claim 32, wherein substantially none of the plurality of electrolytes contacts the electrode disposed in the branch passage when fluid within the branch passage is stationary.
 38. The apparatus of claim 32, wherein each flow path of the plurality of flow paths is connected to a flow path electrode capacitively connected to the electrode.
 39. The apparatus of claim 32, wherein the fluidics system further includes a waste passage extending from the fluidics circuit, the waste passage connected to a waste passage electrode capacitively connected to the electrode.
 40. The apparatus of claim 32, further comprising an analyte in the reaction vessel.
 41. The apparatus of claim 40, wherein the analyte comprise a particle having attached thereto a clonal population of nucleic acid fragments.
 42. The apparatus of claim 40, wherein the electronic sensor is to generate the output signal in response to the analyte or an analyte reaction byproduct proximate thereto.
 43. An apparatus comprising: a reaction vessels coupled to an electronic sensor for monitoring a reaction product in the reaction vessel; a fluidics system for sequentially delivering a plurality of reagents to the reaction vessel, the fluidics system including a plurality of reagent reservoirs in fluidic communication via a plurality of flow paths with a fluidics circuit and to a common passage in fluidic communication between the fluidics circuit and the reaction vessel, a solution reservoir in fluidic communication with the common passage via a branch passage connected with the common passage at a junction between the fluidics circuit and the reaction vessel; a electrode in contact with a solution within the branch passage, the electrode being in electrical communication with the reaction vessel through fluid extending from the branch passage and through the common passage, the electronic sensor generating an output signal depending on a voltage of the electrode; and a plurality of flow path electrodes, each flow path of the plurality of flow paths is uniquely connected to a flow path electrode of the plurality of flow path electrodes, each of the flow path electrodes capacitively connected to the electrode.
 44. The apparatus of claim 43, wherein the electrode provides a reference voltage to the electronic sensor.
 45. The apparatus of claim 43, wherein the reaction vessel includes a well of an array of wells disposed on an array of chemically sensitive field-effect transistor sensors, the electronic sensor comprising a chemically sensitive field-effect transistor sensor of the array of chemically sensitive field-effect transistor sensors.
 46. The apparatus of claim 45, wherein the fluidics system comprises a flow cell in fluid communication with the wells and configured to deliver reagents of the plurality of reagents to each well of the array of wells at substantially the same flow rate.
 47. The apparatus of claim 43, wherein substantially none of the plurality of electrolytes contacts the electrode disposed in the branch passage when fluid within the branch passage is stationary.
 48. The apparatus of claim 43, wherein the fluidics system further includes a waste passage extending from the fluidics circuit, the waste passage connected to a waste passage electrode capacitively connected to the electrode.
 49. A method of monitoring a reaction product in a reaction vessel, the method comprising: flowing a first reagent within an apparatus, the apparatus comprising: a reaction vessel coupled to an electronic sensor for monitoring a reaction product in the reaction vessel; a fluidics system for sequentially delivering a plurality of reagents to the reaction vessel, the fluidics system including a plurality of reagent reservoirs in fluidic communication via a plurality of flow paths with a fluidics circuit and to a common passage in fluidic communication between the fluidics circuit and the reaction vessel, a solution reservoir in fluidic communication with the common passage via a branch passage connected with the common passage at a junction between the fluidics circuit and the reaction vessel; and an electrode in contact with a solution within the branch passage, the electrode being in electrical communication with the reaction vessel through fluid extending from the branch passage and through the common passage, the electronic sensor generating an output signal depending on a voltage of the electrode; and flowing a second reagent within the apparatus.
 50. The method of claim 49, wherein each flow path of the plurality of flow paths is connected to a flow path electrode capacitively connected to the electrode.
 51. The method of claim 49, wherein the fluidics system further includes a waste passage extending from the fluidics circuit, the waste passage connected to a waste passage electrode capacitively connected to the electrode. 